The Constant Escapement will be without any doubt one of the most amazing and meticulously engineered timepiece produced in 2013, a real revolution created by the master watchmakers of Girard Perregaux.

A timepiece with a technology breathtaking, so complicated and yet so simple. Once again the manufacturing Girard Perregaux leaves us spellbound with another piece that looks like it came from another world:

The CONSTANT ESCAPEMENT by GIRARD-PERREGAUX

THE CONSTANT ESCAPEMENT AT A GLANCE

- A revolutionary concept addressing a holy grail of watchmaking, constant force. A breakthrough in the field of chronometry with a completely new architecture and design of the escapement (3 different patents).

- Unprecedented precision: a victory over waning power in traditional mechanical watches, through constant power delivery to the oscillator meaning constant amplitude and constant rate.

- Avant-garde materials and advanced technology. Use of a 14 microns silicon buckled-blade, a strategic component 6 times thinner than a human hair.

- Long power reserve and linear indicator due to an innovative double twin barrel (patent pending). A total length of 3 meters of barrel spring.

A true technical revolution that stunned connoisseurs when some prototypes of the innovative mechanism were first presented, the Constant Escapement is now integrated into the movements driving the new models of Girard-Perregaux’s Haute Horlogerie collection. It has taken five years of research and development in virtually unexplored territory to consolidate and ensure the reliability of this significant step in watchmaking history.

The name, in addition to being a nod to one of the Maison’s historical figures, Constant Girard-Perregaux, also refers to a holy grail in mechanical watchmaking that has perplexed watchmakers since the dawn of time: the constant force. Keeping true to its innovative vision, the brand decided to try using a quite novel approach to achieve it.

The concept presented on that occasion in the form of a functional mechanism was breathtaking, promising and poetic: the design was lightweight and graceful. However, the goal was far from being the result of art for art’s sake, this was a new and convincing answer to the age-old preoccupation in watchmaking: the precision and regularity of a mechanical watch.

To get an idea of what is at stake and truly understand the importance of this innovation, it is worth recalling a few basic notions. The heart of a mechanical watch is ruled by the regulating organ, which manages the flow rate of the energy received from the barrel to drive the gear train and the rotation speed of the hands. The classic image is that of a faucet managing the flow of water.

The main factor is not so much the speed of the beats of this heart, the chosen frequency, but their regularity. The dance can be three in a bar or four in a bar, or even a thousand; but the essential thing is that it keeps the beat over time.

All sorts of systems had been dreamed up before the famous Swiss lever escapement was presented in wristwatches, and became more or less standard. Yet it suffers from one drawback: it can only give back the energy it receives from the barrel, which diminishes drawback: it can only give back the energy it receives from the barrel, which diminishes with time. This energy, which defines its timekeeping accuracy, is too fast to start with, and finishes like a machine running out of steam. A curve, the curse and the bane of watchmakers, illustrates the phenomenon: the curve of the amplitude, or angular displacement of a sprung balance wheel or a pendulum, which lessens towards the end of the run.

The principle of a constant force escapement is that whatever the energy supplied by the barrel, the escapement returns a constant energy to the regulator (balance wheel). To achieve this, they had the brilliant idea of integrating an intermediate device into the escapement, consisting of an extremely thin blade that stores the energy up to na invariable threshold bordering on instability, and then transmits it all instantaneously, before recommencing the cycle.

The inspiration came from an experiment, which anyone can repeat by holding a train ticket vertically between thumb and forefinger, bending it to form a C or an open round bracket. If you then apply pressure from the side you will feel resistance until the moment when the card snaps to the other side to mirror its former shape, and close the round bracket. Try it with a business card, it works every time.

The phenomenon of instability is known as buckling, which is the passage from a state of compression to one of bending. Spring specialists thus speak of buckled blades. Here, the silicon blade measures a quarter of a hair’s thickness and plays the role of a microaccumulator of energy. This blade is flexed to a point as close as possible to its unstable state, and only needs an infinitesimal quantity of energy - a micro-impulse given by the balance wheel (less perturbing than in a lever escapement) – for it to snap from one state to the other, and in the process, to push the balance wheel forward, compensating for the variable energy of the barrel and liberating the same quantity of energy every time.

Unlike other systems that propose a constant force averaged over time, this is an authentic constant force escapement, as the force is instantaneous and continuous. And indeed, it is quite measurable using laboratory testing methods.

The designers chose a symmetrical double construction. This was not for aesthetic reasons, but to balance the forces at the center of the balance wheel and avoid a concentration of constraints at that point in order to ensure totally unencumbered rotation.

The blade is formed in one piece with the frame which holds it by both ends and plays a decisive role in the very precise locking of the point of contact for the micro-impulse which will make it snap over. The relatively simple principle brings with it the need for absolute precision to put it into practice, which would have been impossible before the use of silicon and the arrival of new part manufacturing techniques, such as deep reactive ion etching (DRIE). The partnership with the CSEM (Swiss Electronics and Micro-engineering Centre) in Neuchâtel, Switzerland was decisive. Watchmaking experts and physicists carried out complex calculations to determine the characteristics of the blade, and the many factors governing the buckling point. In the end, the structure of the device incorporating the blade is monolithic. It is held in virtual levitation and undergoes no friction except at the moment of the impulse and the flexing of the blade. The energy of the blade is directly transmitted back to the balance wheel.

Since the blade is the key element of the Constant Escapement, its natural vibration governed the choice of frequency: it will be 3 Hz (21,600 vibrations per hour) for the magic to work. But the future remains open, and tests have already been carried out at other frequencies. In any case, the challenge here is not about high frequencies.

The two escapement wheels look nothing like those found in a lever escapement. They have three teeth for a frequency of 3 Hz, and would need four for 4 Hz. The movement was designed to run for several days with a linear power reserve indicator on the dial, demonstrating the efficiency of this escapement in the long run. The energy is supplied by two barrels coupled in parallel (a new patented design): the cover and the ratchet are a single piece to maximize the thickness available and each drum contains two springs stacked in series. Two other patents have been filed: one for the blade naturally, filed back in 2008, the other for the incorporation of limit stops in a flexible system.

While silicon was the material of choice for its ideal properties in the design and manufacture of the blade, it may be replaced by other materials for escapement wheels, while the movement blanks are in brass coated in black PVD for a contemporary look. The movement’s aesthetic is meant to be technical, three-dimensional, but also to give a nod to tradition, with references to the brand’s icons such as its famous three Bridges, laid out in a fresh way on its dial side, while on the back there are two arrow bridges.

To cap it all, this revolutionary movement looks ahead to after sales servicing right from the drawing board stage: the whole of the escapement is a module and can be handled by a specialized watchmaker.

FIRST MODEL IN THE CONSTANT ESCAPEMENT COLLECTION

In housing this unique movement with its totally original and innovative escapement, the case had to do justice to the feat of engineering, to showcase it without hiding behind it.

Launching the Haute Horlogerie Constant Escapement collection, the first model to be equipped with the device stands out with its resolutely technical and contemporary design, with a nod Girard-Perregaux’s codes and its creative tradition. The movement takes its place in a comfortable round 48 mm diameter case in white gold with a curved case band.

To offer maximum visibility to the escapement itself, with its butterfly wing frame and the vibrating blade in its central axis, the hours and minutes occupy a sub-dial off-centered at 12 o’clock. This is flanked by the two energy reservoirs in the shape of the double barrels. Logically linear, the power reserve indicator is placed at 9 o’clock.

The whole of the lower part of the watch is reserved for the Constant Escapement, which occupies center stage and steals the show, beating at the frequency of 3 Hz or 21,600 vibrations per hour. Under the antireflective sapphire glass the brand’s three emblematic Bridges are visible and play their structural role in a novel layout.

This manually wound caliber is no thicker than 8 mm, while the case that houses it measures 14.63 mm, with a wide open sapphire glass back secured with 6 screws offering another angle of view on the remarkable 3-D construction of this unique movement.

With its hand-sewn alligator strap and folding clasp, the model will be offered in Girard-Perregaux’s Haute Horlogerie collection.